Abstract: A method of controlling a mechanical testing instrument includes estimating a young's modulus, and applying force during a first time interval then comparing distance measured to expected distance; predicting a distance based on a first slope applying displacement distance and recalculating the slope; providing a corrected force applied for the proper displacement based on measured modulus and correction factor and adjusting into time and distance coherence; applying a force versus time regime interval and predict deformation at the end of the second interval measuring true deformation distance after the next interval; calculating the ‘true’ slope’ based on the extrapolated actual slope; calculating a slope to apply for desired distance; and repeating measurement and correction steps, using the actual slope as the prediction basis. A system for carrying out the method is also disclosed using a data acquisition board.

Abstract: The invention discloses a method for testing of injectable biomaterials and their performance in the treated materials, to obtain functional properties of the biomaterials and of the specimen injected with that biomaterial. The purpose of the method is to measure these properties during injection of a biomaterial into a target object, then measure the properties of a target object specimen after the injection, and then combine these results using material model-free data processing with possible prediction.

Abstract: A rheometer for determining and/or monitoring the flow behavior of viscous fluids, in particular plastic melts and plastic solutions, includes a housing, in which at least one substantially rectilinear channel is formed between an inlet opening and an outlet opening, the channel having a rectangular cross section, and a plurality of pressure measuring devices which are arranged along the channel, wherein the channel is provided over its length with a cyclically narrowing and widening cross section.

Abstract: A system and method for inspecting the quality of the metal powder based on automatic visual inspection.

Abstract: In various embodiments, a method for determining at least one pore-related parameter of a porous structure is provided. The method includes supplying a volatile liquid into a chamber. The method also includes coating a first surface of the porous structure with an evaporation preventing substance. The method further includes placing the coated porous structure within the chamber. The method additionally includes determining an effective mass of the chamber over a period of time. The method also includes determining the at least one pore-related parameter of an uncoated second surface of the coated porous structure based on the effective mass determined. The second surface of the porous structure is opposite the first surface of the porous structure.

Abstract: A flow cytometry system and method for quantification of fluorescently labeled virus particles smaller than 1 micron in size measures and controls sample fluid flow rate to an investigatory flow cell at a rate below 5000 nanoliters per minute and calculates in real time particle concentration in the sample fluid using measured flow rated data flow rate data and with correction for sample fluid flow rate fluctuations.

Abstract: A liquid membrane 100 is formed by jetting a liquid sucked from a recovery reservoir 11a and pressurized using a pump 12 from a nozzle of a liquid membrane cartridge 20. The formed liquid membrane 100 makes contact with a slope wall of the liquid membrane cartridge 20 along a surface of the liquid membrane 100. The liquid running down from the slope wall is recovered and stored in the recovery reservoir 11a in order to recover the liquid running down along the slope wall in a decelerated state into the recovery reservoir 11a. As a result, it is possible to prevent air bubbles from being generated by agitation of a liquid of the recovery reservoir 11a when the liquid enters the recovery reservoir 11a.

Abstract: An illumination device 11 has: a light source 1 for emitting polarized light having a Gaussian beam profile and including a first polarized light component and a second polarized light component orthogonal to each other; and a spiral phase element for imparting a phase modulation amount which increases for each predetermined step amount along a circumferential direction about an optical axis OA to the first polarized light component of transmitted polarized light from the light source 1 and making the beam profile of the first polarized light component a Laguerre-Gaussian beam profile, and forming a composite beam having a top-hat-shaped beam profile in which the second polarized light component of the transmitted polarized light from the light source 1 and the first polarized light component having a Laguerre-Gaussian beam profile are synthesized.

Abstract: Described is a method for quantifying the amount of optically interfering gas impurities in a gas detection system comprising a sample gas inlet, a reference gas inlet, a gas modulation valve, and an infrared absorption gas detector used for analysis of methane or natural gas, wherein the gas modulation valve alternatingly connects the sample gas inlet to the gas detector during a sample gas time period and the reference gas inlet to the gas detector during a reference gas time period. The method includes measuring an infrared absorption for at least two different sample gas concentrations in the gas detector achieved via respective different ratios from the sample gas time period and the reference gas time period, and comparing amplitudes of different measurement signals of the at least two different sample gas concentrations with calibration functions to assess an actual gas impurity concentration in the sampled gas.

Abstract: A method of imaging a specimen container and/or specimen. The method includes providing a specimen container containing a specimen at an imaging location, providing one or more cameras configured to capture images at the imaging location, providing one or more light sources adjacent to the imaging location, illuminating the imaging location with the one or more light sources, and capturing multiple images including: specimen images of the image location at multiple different exposures, with the specimen container and specimen being present at the image location. Quality check modules and specimen testing apparatus including a quality check module are described herein, as are other aspects.

Abstract: In a method and apparatus, a property of an optically diffuse medium including a first optical absorber having a first concentration and a second optical absorber having a second concentration is determined. A surface area of the medium is imaged at multiple wavelengths around an isosbestic wavelength of the first absorber and the second absorber. A reflectance spectrum of the medium at the surface area at the multiple wavelengths is determined. A derivative of the determined reflectance spectrum around the isosbestic wavelength is determined. From the derivative, a concentration ratio of the first concentration and the second concentration is estimated.

Abstract: A method for determining in situ and in real time at least one suspended sediment property in a medium, the suspended sediment comprising a mineral and an organic fraction. The method comprises the steps of (a) measuring light absorbance with a submersible ultraviolet-visible spectrometer, the ultraviolet-visible spectrometer being configured to analyse to analyse light absorbance at wavelengths which are comprised between 220 nm and 730 nm and of (b) correlating the light absorbance to the properties of the suspended sediment, in various instances by using the Beer-Lambert's law. The method is remarkable in that the step (b) is performed by using one model calibrated for deriving the properties of the suspended sediment from the light absorbance.

Abstract: Techniques for detecting narcotics such as tetrahydrocannabinol (THC) or other aerosols such as cannabinoids, opioids, etc., in an exhaled breath using infrared spectroscopy are provided. An example of an apparatus for sensing THC according to the disclosure includes a tunable laser source, at least one photodetector, a sample cell disposed between the tunable laser source and the at least one photodetector, and at least one processor operably coupled to the tunable laser source and the at least one photodetector and configured to provide a control signal to the tunable laser source, determine a spectral absorption line or group of absorption lines associated with THC based on an intensity of infrared light detected by the at least one photodetector, and determine a THC concentration value based on the spectral absorption line intensity. A laser-based apparatus for sensing narcotics in exhaled breath may include a single, dual, or multi-optical frequency comb spectrometer.

Abstract: The gas detection device according to the present invention is provided with: a first image processing unit for generating a first binary image for indicating in binary fashion the inside and outside of a first region indicating water vapor and a gas to be detected, on the basis of a first image generated using an optical filter having a first pass wavelength band including at least an absorption wavelength band of the gas; a second image processing unit for generating a second binary image indicating in binary fashion the inside and outside of a second region indicating the water vapor, on the basis of a second image generated using an optical filter having a second pass wavelength band different from the absorption wavelength band; and a third image processing unit for calculating a difference between the first binary image and the second binary image.

Abstract: Systems and methods are provided for measuring spectral hemispherical reflectance. One embodiment is a system that includes a laser that emits a beam of light, and an optical chopper disposed between the laser and a sample. The chopper blocks the beam while the chopper is at a first angle of rotation, redirects the beam along a reference path while the chopper is at a second angle of rotation, and permits the beam to follow a sample path through the chopper and strike the sample while the chopper is at a third angle of rotation. The system also includes a hollow sphere that defines a slot through which the sample path and reference path enter the sphere. The hollow sphere includes a spectral hemispherical reflectance detector, a mount that receives the sample at the sphere, and an actuator that rotates the sphere about an axis that intersects the sample.

Abstract: The invention relates to a method for improving the screening of histological samples, especially samples that may include cancerous or precancerous cells, or cells having other disease states. The method involves analysing a sample obtained from a subject and comprises the steps of providing the spectra produced by scanning the sample using FTIR spectroscopy and identifying or sorting the cells in the sample according to the spectrum each produces.

Abstract: A water content evaluation apparatus which evaluates water content of a part of a plant is provided. A water content at each of irradiation positions of the part of the plant is calculated based on a first reflection light of a laser reference beam, having a first wavelength that is not absorbed by water, that is reflected at all the irradiation positions of the plant and a second reflection light of a laser measuring beam, having a second wavelength that is absorbed by water, that is reflected at all the irradiation positions of the plant. Irradiation positions of the plant in which the water content is equal to or larger than at least one predetermined threshold level are displayed, in at least one corresponding predetermined color.

Abstract: There are provided a terahertz wave spectral dispersing unit 13 for spectrally dispersing a terahertz wave to be generated from a terahertz wave generating semiconductor 12 into two waves, a terahertz wave focusing unit 14 for focusing a terahertz wave transmitted through a sample liquid film 101 and a terahertz wave transmitted through a reference liquid film 102, and a terahertz wave detecting semiconductor 15 for detecting the focused terahertz wave, and it is possible to detect the terahertz wave transmitted through the sample liquid film 101 and the terahertz wave transmitted through the reference liquid film 102 in an interference state, thereby offsetting a noise made by a stripe-shaped wave generated on the sample liquid film 101 and a noise made by a stripe-shaped wave generated on the reference liquid film 102.

Abstract: A first data acquisition processing unit acquires light intensity distribution data on the basis of an image of measurement light that has entered a camera. A second data acquisition processing unit acquires light intensity distribution data on the basis of the detected intensity of measurement light detected by a detector. A refractive index measurement processing unit measures the refractive index of a sample on the basis of the light intensity distribution data acquired by the second data acquisition processing unit. A determination processing unit determines whether the refractive index of the sample measured by the refractive index measurement processing unit is acceptable on the basis of the peaks of the light intensity distribution data acquired by the first data acquisition processing unit and second data acquisition processing unit.

Abstract: An optical apparatus for obtaining a reflectance spectrum includes a first means for generating a light, a second means for transferring and receiving the light on a substrate, a third means for collecting a diffusely reflected light, and a fourth means for separating the diffusely reflected light from a specular reflected light to obtain information about a concentration of a chromophore in the substrate. The second means is an optic probe made of Poly(methyl methacrylate) (PMMA) material including an inner rod and an outer rod, the inner rod is nested within the outer rod for collection and for illumination, the inner rod and the outer rod are coaxial, the inner rod is longer than the outer rod, the inner rod is isolated from the outer rod with a semi mirrored isolator, the reflected light is reflected from deep within the substrate by the inner rod.

Abstract: An overlay metrology system includes an overlay metrology tool configurable to generate overlay signals with a plurality of recipes and further directs an illumination beam to an overlay target and collects radiation emanating from the overlay target in response to the at least a portion of the illumination beam to generate the overlay signal with the particular recipe. The overlay metrology system further acquires two or more overlay signals for a first overlay target using two or more unique recipes, subsequently acquires two or more overlay signals for a second overlay target using the two or more unique recipes, determines candidate overlays for the first and second overlay targets based on the two or more overlay signals for each target, and determines output overlays for the first and second overlay targets based on the two or more candidate overlays for each target.

Abstract: A method may comprise: exposing a substituted chromone dissolved in a solvent to a sample; taking a fluorescence measurement of the sample after exposure to the substituted chromone; and determining a presence or absence of one or more ions in the sample, a concentration of the one or more ions in the sample, or both based on the fluorescence measurement.

Abstract: This invention is in the field of fluorescence imaging and relates to a new near infrared (NIR) reactive oxygen species (ROS) sensor designed with controlled fluorescence on-off switching mechanism.

Abstract: Methods, systems and reagents are provided for detecting and quantifying carbonyl containing moieties in a variety of sample types.

Abstract: For an imaging method for presenting fluorophores (5) by optical excitation, spontaneous emission of fluorescence and detection of same, a single, conventional sensor (6) is used having at least two color channels, which detect an excitation light used to excite the fluorophore (5) and the fluorescence emitted by the fluorophore (5) with different sensitivities. Due to the different spectral distribution of the sensitivity of the color channels, it is possible to separate the component of the excitation light from the component of the fluorescence, in particular in a specific pixel, from one another by processing output signals of said color channels, in particular by conversion into a color space and/or by calculation of color saturation values. From this, the intensity of the fluorescence can be deduced, preferably taking account of a relative luminance measured by the color channels, even though reflected excitation light reaches the color channels, in particular in an unfiltered manner.

Abstract: A Laser Induced Breakdown Spectrocopy (LIBS) system (2) for the analysis of a sample pellet (12) of a consolidated granular material retained in a tubular container (20), the system (2) comprising a laser source (4) configured to emit a pulsed laser beam (6) towards an exposed surface of the sample pellet (12); and a sample station (18) configured to hold the tubular container (20) with the sample pellet (12) orientated to present the exposed surface towards the pulsed laser beam and comprising an actuator configured to slide the sample pellet (12) along a movement axis out of the tubular container (20) and thereby present a portion of an outer surface (10) of the sample pellet (12) previously constrained by an inner surface of the tubular container (20) as the exposed surface.

Abstract: A heating chamber (1) for a heating furnace is proposed, with which electrothermal vaporization of impurities from samples can be effected in order to be able to then analyze them spectrometrically. The heating chamber has a wall (3), a sample reception area (5), a nozzle area (7) and two electrical connection areas (9, 11). The heating chamber (1) is specially configured such that an electric current flows through the wall (3) in such a way that a heating capacity caused by it is higher in the nozzle area (7) than in the sample reception area (5).

Abstract: A measuring method for measuring an isotope ratio of an element present in a material includes a plurality of elements, the method comprising the following steps: a step of applying at least one laser beam to the material so as to generate a plasma, the plasma being able to emit a light spectrum comprising a plurality of spectral lines emitted by the elements of the material; a measuring step able to measure the profile of at least one spectral line of interest emitted by the element of interest, the measuring step comprising carrying out, with a spectrometer, at least one analysis of the light spectrum emitted by the plasma; a processing step able to note in the profile of the spectral line of interest the optimal wavelength corresponding to a point of equilibrium; and a step of determining the isotope ratio depending on the noted optimal wavelength.

Abstract: Provided is an implement for inspection capable of measuring the concentration of a test substance with high accuracy. The implement for inspection according to the present invention is an implement for inspection used for measuring the concentration of a test substance that includes a compound for reacting with a test substance to form a granular substance or a compound which is for being bound to the test substance and is a granular substance, and a wall portion having a periodic structure on its surface.

Abstract: Disclosed herein are methods and systems for distinguishing a target gas from other target gases, which involve a configuration of a light source (120) and paper tape (110) such that light (112) emitted from the light source (120) can reflect off the paper tape (110). A reflected portion (114) of the light (112) can be detected, as well as the humidity and optionally the temperature. The light (112) can emit in at least three wavelengths selected from red, green, blue, and ultra-violet wavelengths, and pattern recognition can be used to identify and/or distinguish the target gas from the group of target gases based on wavelength detection information and the one or more of the humidity and the temperature.

Abstract: Disclosed are methods and systems for detecting a target gas, which involve a configuration of a light source (120) and paper tape (110) such that light (112) emitted from the light source (120) can transmit through the paper tape (110). At least some of the portion of light (112) which transmits through a paper tape (110) can be detected with a detector (130). Detection of the light (112) can be used to determine presence or absence of low concentrations of the target gas.

Abstract: A detection device 1 includes an irradiator 3, a photodiode 4, and an evaluation portion 5. The irradiator 3 emits laser light to a surface of a substrate W. The light resulting from the laser light reflected at the surface of the substrate W is incident on the photodiode 4, and the photodiode 4 detects a first position P1 at which the light is incident. The evaluation portion 5 includes a calculation portion and a detection portion. The calculation portion calculates an inclination of the surface of the substrate W on the basis of the first position P1 and a second position P2 at which light is incident on the photodiode 4 when the laser light is reflected at the surface of the substrate W that is flat. The detection portion detects a defect formed on the surface of the substrate W on the basis of the inclination.

Abstract: Provided are CT scanning systems and architectures that utilize a unique approach to scanning large objects. Various embodiments of the architecture incorporate a scanning platform and a turntable. The scanning platform may be mounted horizontally. The vertical offset between the scanning platform and the turntable may be changed during a scan. A pallet or other object can be moved into a scanning area under the scanning platform. Both the vertical offset between the scanning platform and the turntable may be changed and the turntable may be rotated during a scan. Scan data may be used to generate a three dimensional image. Additional objects can be quickly positioned (once the vertical offset is adjusted) for subsequent scans allowing for greater throughput than conventional approaches.

Abstract: An analysis apparatus, an analysis method, and an analysis program by which even unskilled ones can perform quantitative analysis of a composition of high-performance cement with high precision.

Abstract: An image processing device includes a spectrum acquisition unit that acquires a plurality of spectra that respectively have different measurement energy ranges and energy resolutions and are acquired using an X-ray spectrometer having a plurality of dispersion elements with different spectral characteristics, a graph generation unit that sets the plurality of spectra on a single graph having an axis of an ath root of the energy (where a?2) as a first axis, and an axis based on an X-ray intensity as a second axis, and a display control unit that executes control to display the graph generated by the graph generation unit on a display unit.

Abstract: In a device for controlling the temperature of a test sample in a measuring device for measuring material properties of the test sample, comprising a measuring cell for receiving the test sample, at least one temperature controlling element, and a thermal storage element coupled to the temperature controlling element to transfer heat, wherein means are provided for changing the thermal resistance between the thermal storage element and the measuring cell in order to selectively couple or decouple the thermal storage element and the measuring cell in terms of heat transfer, the ratio of the thermal capacity of the thermal storage element to the thermal capacity of the measuring cell is greater than 1:1, preferably at least 2:1, preferably at least 5:1.

Abstract: Electrochemical impedance spectroscopy (EIS) may be used in conjunction with continuous glucose monitoring (CGM) to enable identification of valid and reliable sensor data, as well implementation of Smart Calibration algorithms.

Abstract: We disclose herein a method for heating a gas sensing material formulation on a microhotplate which comprises: a dielectric membrane formed on a semiconductor substrate comprising an etched portion; and the gas sensing material formulation being located on one side of the dielectric membrane. The method comprising: selectively heating the gas sensing material formulation using an infra-red (IR) heater located over the substrate, and controllably cooling the semiconductor substrate using a cooling baseplate provided under the substrate and using an insulating medium located between the substrate and the cooling base plate so that a gas sensing structure is formed on said one side of the dielectric membrane from the gas sensing material formulation.

Abstract: Disclosed is a gas sensor for detecting a measurement target gas in a measurement gas atmosphere, including first and second sensor elements respectively installed in first and second inner spaces of first and second installation parts. The first and second sensor elements have respective heating resistors connected in series and each has a resistance value that varies with change in temperature thereof so that the concentration of the measurement target gas can be calculated according to a potential between the heating resistors of the first and second sensor elements with the application of a constant voltage. The first and second installation parts are located at such positions that allow a maximum temperature difference of 0.4° C. or less between the first and second inner spaces during change in atmosphere temperature from 0° C. to 80° C.

Abstract: A change in an imaginary part of a complex dielectric constant of an inspection object containing moisture is detected as a change in an oscillation frequency. A sensor device includes an oscillation unit that is formed in a semiconductor integrated circuit and an oscillation frequency detection unit that detects an oscillation frequency of the oscillation unit. The oscillation unit has capacitors that are connected to an inspection object in series and changes the oscillation frequency in accordance with a complex dielectric constant of the inspection object.

Abstract: A sensor arrangement (10) comprises a capacitive sensor (11) with a first electrode line (12), a second electrode line (16) and a third electrode line (20) and a sensitive layer (30) arranged at the first, the second and the third electrode line (12, 16, 20). The sensor arrangement (10) comprises a readout circuit (50) that comprises a capacitance-to-digital converter (51), is coupled to the first, the second and the third electrode line (12, 16, 20) and is configured to generate a first measurement signal (S1) using the first and the second electrode line (12, 16) and a second measurement signal (S2) using at least the third electrode line (20).

Abstract: The present invention is to provide a metal paste capable of forming electrodes which have sufficient electrode activity and electroconductivity as compared with conventional ones and are useful as the sensor electrodes of various gas sensors. The present invention relates to a metal paste for gas sensor electrode formation formed by dispersing conductive particles including Pt or a Pt alloy and ceramic powder into a solvent and the metal paste further includes inorganic-oxide particles including alumina and insoluble organic particles or carbon or diamond powder, the ceramic powder including a ceramic powder having a particle diameter of 0.5 ?m or larger in an amount of 10-80% by mass based on the whole ceramic powder.

Abstract: An electrochemical sensor comprises a substrate disposed within a housing, a plurality of electrodes disposed on a first surface of the substrate, an electrolyte disposed over at least a portion of each electrode of the plurality of electrodes, and a capillary disposed through the substrate. The capillary is configured to provide a diffusion pathway for a target gas to pass from an exterior of the housing to one or more of the plurality of electrodes.

Abstract: A solid-state, low power microheater sensor platform that is configurable with selected metal oxide films for particular gas sensing applications is described. The sensor platform is configured by selecting a chemiresistive or catalytic material that is suitable for detecting a desired gas and then forming a porous nanostructured film on the designated surfaces of the microheater platform. Also described are methods for creating a highly porous, nanostructured metal oxide film in a controlled location from a liquid precursor using a localized heat source. By fast annealing deposited liquid precursors with the microheater, a highly porous, nanocrystalline metal oxide film can be generated in-situ and locally on the sensor platform.

Abstract: Disclosed is a gas sensor for detecting a measurement target gas in a measurement gas atmosphere, including: a first sensor element; a first installation part defining a first inner space in which the first sensor element is installed; and a casing accommodating therein the first installation part. The casing has an opening formed to introduce the measurement target gas into an inside of the casing. The first installation part has: a first gas introduction hole formed to provide communication between the first inner space and the inside of the casing; and a membrane member arranged to cover the first gas introduction hole and having permeability to water vapor and substantially no permeability to the measurement target gas. At least a portion of the first installation part in contact with the membrane member is made of insulating ceramic material or resin material.

Abstract: Apparatus and methods are disclosed for single molecule field effect sensors having conductive channels functionalized with a single active moiety. A region of a nanostructure (e.g., such as a silicon nanowire or a carbon nanotube) provide the conductive channel. Trapped state density of the nanostructure is modified for a portion of the nanostructure in proximity with a location where the active moiety is linked to the nanostructure. In one example, the semiconductor device includes a source, a drain, a channel including a nanostructure having a modified portion with an increased trap state density, the modified portion being further functionalized with an active moiety. A gate terminal is in electrical communication with the nanostructure. As a varying electrical signal is applied to an ionic solution in contact with the nanostructure channel, changes in current observed from the semiconductor device can be used to identify composition of the analyte.

Abstract: In various embodiments of the present disclosure, a molecular electronics sensor array chip comprises: (a) an integrated circuit semiconductor chip; and (b) a plurality of molecular electronic sensor devices disposed thereon, each of said sensor devices comprising: (i) a pair of nanoscale source and drain electrodes separated by a nanogap; (ii) a gate electrode; and (iii) a bridge and/or probe molecule spanning the nanogap and connecting the source and drain electrodes, wherein the molecular electronic sensor devices are organized into an electronically addressable, controllable, and readable array of sensor pixels.

Abstract: Systems, methods and devices relating to measuring free chlorine in liquid samples. An enhanced graphite electrode and sensors comprising the same are provided. The enhanced graphite electrode in conjunction with a reference electrode and a counter electrode can be used in a chronoamperometry mode to detect concentrations of free chlorine in liquid samples, especially static liquid samples. The enhanced graphite electrode can also be used in conjunction with a counter/reference electrode in a pulsed amperometric detection mode to detect concentrations of free chlorine in liquid samples, especially static liquid samples.

Abstract: The present disclosure relates to an interdigitated electrode biosensor using dielectrophoresis, including an insulating layer configured to fully cover a sensor forming region of a substrate, a first interdigitated microelectrode configured such that a plurality of first protruding electrodes is arranged in a shape of a comb on the substrate, a second interdigitated microelectrode configured such that a plurality of second protruding electrodes is arranged in a shape of a comb and each interdigitates with the plurality of first protruding electrodes formed in the first interdigitated microelectrode, and a plurality of receptors that is immobilized in a space between the first interdigitated microelectrode and the second interdigitated microelectrode and reacts specifically to target biomaterials, wherein different voltages are uniformly or nonuniformly applied to the first interdigitated microelectrode and the second interdigitated microelectrode to generate a dielectrophoretic force by a nonuniform electric

Abstract: The disclosure provides an analysis chip that includes a microchip employing capillary electrophoresis and a cartridge.